Methods and apparatus for measuring the bit state of a particular element in an array of passive nonlinear elements that are insensitive to loading effects from external connections to the array. In one embodiment, a switching element is used to electrically isolate the elements in the array from the external load.
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1. An information-storage circuit comprising:
a first set of generally parallel conductive lines;
a second set of generally parallel conductive lines that is generally perpendicular to and overlapping with the first set of lines;
a plurality of bit states, with each bit state of said plurality occurring in the general vicinity of a region of overlap between a line from the first set of lines and a line from the second set of lines, and the state of any bit state being determined by the presence or absence of a nonlinear element bridging a line from the first set of lines and a line from the second set of lines at a region of overlap; and
output-detection circuitry for determining a selected bit state without interference from external loading.
13. A method for accessing an information-storage circuit without interference from external loading effects, the method comprising:
providing a first set of generally parallel conductive lines;
providing a second set of generally parallel conductive lines that is generally perpendicular to and overlapping with the first set of lines;
providing a plurality of bit states, with each bit state of said plurality occurring in the general vicinity of a region of overlap between a line from the first set of lines and a line from the second set of lines, and the state of any bit state being determined by the presence or absence of a nonlinear element bridging a line from the first set of lines and a line from the second set of lines at a region of overlap; and
providing output-detection circuitry for determining a selected bit state without interference from external loading.
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The present application claims the benefit of U.S. Provisional Application No. 60/787,247, filed on Mar. 28, 2006, the entire disclosure of which is hereby incorporated by reference as if set forth in its entirety herein. The present application is also related to the applications having docket numbers NUP-009US2 and NUP-009US3, filed herewith.
The present invention relates generally to passive memory devices, and more specifically to the off-chip detection of bit states on a passive memory device.
There are many forms of semiconductor-based digital memory. The most common forms-such as static random access memory (SRAM), dynamic random access memory (DRAM), and Flash memory-typically require complicated semiconductor fabrication processes to achieve high memory densities. This goal of high density-measured by the number of bits of data per square centimeter-is desirable for many reasons, not the least of which is to achieve a low cost per bit of storage given the expense of fabrication.
Diode memory arrays are one particular form of semiconductor-based digital memory. U.S. Pat. No. 5,673,218 (“the '218 patent”), for example, describes a memory circuit in which diodes serve as the memory elements. This type of circuit can achieve a low cost per bit of storage due to the simplicity of the semiconductor processing required to fabricate diodes. During fabrication, a diode-only process might require only five or six masks using photolithography, or three or four chemical-mechanical polishing (CMP) and etch steps using topolithography. In contrast, a typical process to create a Flash memory can require 35 masks during fabrication.
Referring again to
The present invention provides methods and apparatus for measuring the bit state of a particular element in an array of passive nonlinear elements that are insensitive to loading effects from external connections to the array.
In one aspect, embodiments of the present invention provide an information-storage circuit having a first set of generally parallel conductive lines, and a second set of generally parallel conductive lines that is generally perpendicular to and overlapping with the first set of lines. The circuit also has a plurality of bit states, with each bit state of said plurality occurring in the general vicinity of a region of overlap between a line from the first set of lines and a line from the second set of lines, and the state of any bit state being determined by the presence or absence of a nonlinear element bridging a line from the first set of lines and a line from the second set of lines at a region of overlap. Lastly, the circuit includes output-detection circuitry for determining a selected bit state without interference from external loading. The nonlinear element may be selected from the group consisting of a diode, a series combination of a diode and a contact opening, and a series combination of a diode and a one-time programmable element.
In one embodiment, the output-detection circuitry determines the selected bit state by measuring charge. In this embodiment, each measured charge is stored on a capacitance. In another embodiment, the circuit includes a plurality of capacitances, each capacitance associated with a nonlinear element. Each capacitance may occur between one of the nonlinear elements and a line selected from the first set of lines or the second set of lines, or between a line from the first set of lines and a line from the second set of lines. In still another embodiment, the output-detection circuitry includes a capacitive switching circuit.
The circuit may be electrically connected to an external device, and the electrical connection may induce a loading effect. The output-detection circuit may further include a comparator in the external device. The comparator may be operated synchronously with the information-storage circuit. The comparator may detect a change in at least one of charge, voltage and current to determine a digital output state.
In another aspect, embodiments of the present invention provide a method for accessing an information-storage circuit without interference from external loading. A first set of generally parallel conductive lines is provided, as is a second set of generally parallel conductive lines that is generally perpendicular to and overlapping with the first set of lines. A plurality of bit states are provided, with each bit state of said plurality occurring in the general vicinity of a region of overlap between a line from the first set of lines and a line from the second set of lines, and the state of any bit state being determined by the presence or absence of a nonlinear element bridging a line from the first set of lines and a line from the second set of lines at a region of overlap. Lastly, output-detection circuitry is provided for determining a selected bit state without interference from external loading. The nonlinear element may be selected from the group consisting of a diode, a series combination of a diode and a contact opening, and a series combination of a diode and a one-time programmable element.
In one embodiment, providing output-detection circuitry comprises providing output-detection circuitry that determines the selected bit state by measuring charge. In this embodiment, a plurality of capacitances is provided, wherein each measured charge is stored on a capacitance. In another embodiment, a plurality of capacitances is provided, with each capacitance associated with a nonlinear element. Each capacitance may occur between one of the nonlinear elements and a line selected from the first set of lines or the second set of lines. In still another embodiment, providing output-detection circuitry comprises providing output-detection circuitry including a capacitive switching circuit.
The method may further include electrically connecting the circuit to an external device, and the electrical connection may induce a loading effect. Providing output-detection circuitry may further include providing output-detection circuitry comprising a comparator in the external device. The comparator may be operated synchronously with the information-storage circuit. The comparator may detect a change in at least one of charge, voltage and current to determine a digital output state.
The foregoing and other features and advantages of the present invention will be made more apparent from the description, drawings, and claims that follow.
The advantages of the invention may be better understood by referring to the following drawings taken in conjunction with the accompanying description in which:
In the drawings, like reference characters generally refer to corresponding parts throughout the different views. The drawings are not necessarily to scale, emphasis instead being placed on the principles and concepts of the invention.
Embodiments of the present invention provide methods and apparatus to facilitate access to bit states in a memory array. Particular embodiments facilitate address decoding and on-chip output generation using passive elements, such as diodes, or diodes in combination with a contact opening or a one-time programmable element. Embodiments of the present invention allow for the detection of the generated output outside the chip package in a manner that does not interfere with the operation of the memory array.
Memory Array and Elements
The space between the two sets of conductors 300, 304 holds a plurality of vertically-oriented rectifier elements 308, here P-N junction diodes. To provide an array having a maximum bit density per unit area, a diode 308 is formed at each region of overlap between the first set of conductors 300 and the second set of conductors 304. The diode 308 may be formed in series combination with a capacitor or one-time programmable element (not shown).
The design of
One embodiment of the present invention utilizes semiconductor memory fabricated in three dimensions (not shown). One such embodiment is described in U.S. Pat. No. 6,956,757, assigned to Contour Semiconductor, Inc., the contents of which are hereby incorporated by reference, although other three dimensional semiconductor memories may be utilized with various embodiments of the present invention.
With reference to
While
Row and Column Decoder Design
As with conventional random access memories organized in an array, in a diode array any particular accessed bit of memory is located at the intersection of a particular selected row and a particular selected column. The selection of a particular row or column in an array is typically controlled using a decoder that, as discussed above, demultiplexes a plurality of coded inputs into a larger set of decoded outputs.
There are several criteria to be considered when designing decoders for a diode memory array. First, to read a particular bit state, the diode associated with that state must forward biased and rendered conductive. In the exemplary diode array shown in
Second, the difference between logic HIGH and logic LOW voltage levels on chip should be sufficient to forward bias a selected memory-bit diode. Third, the selection of the load device must be considered as, with reference to
It may be possible to address this problem utilizing a larger voltage span for input signals, but the magnitude of input signals may ultimately be limited by the breakdown voltage of the individual elements in the array. The decoder depicted in
Address Decoder Operation
Diode logic gates, like other discrete logic gates, may be operated either statically or dynamically. In the case of dynamic operation, it is assumed that there is some equivalent capacitance at the output, shown in
With reference to
This discussion of operation applies to the diode-load version of the diode logic gates. If the gates instead have resistive loads, for example, then the pullup impedance cannot be put in an OFF or high-impedance state, since a resistive load is always conductive. Even with a resistive load, however, dynamic operation may be implemented if the logic driving the outer end of the load resistor can be put into a high-impedance state using a logic function such as a tristate gate.
Unfortunately, the dynamic behavior of diode logic is restrictive. The precharge state is the state determined by the load device, so for positive logic the precharge state is always HIGH, while for negative logic the precharge state is always LOW. The preferred precharge state for a column decoder, however, is the opposite. Accordingly, the dynamic behavior of diode logic typically requires the column decoder to be operated statically during part of the read cycle. At this time, it is understood that this restriction may be avoided utilizing an inverting function or device.
Static versus Dynamic Decoder Operation
As described above, to select a single memory diode in an array, the conductors associated with the diode must be biased so as to forward bias the diode. For example, in the embodiment of
One implementation of a row address decoder and a column address decoder would operate both decoders as static diode logic gates, connecting the pull-up and pull-down load devices to constant power supply pins, i.e., VDD or GND. Unfortunately, such an implementation would consume a significant amount of power, partly due to presence of a logic gate associated with each row and column. For example, for a one megabit array there would be approximately 2,000 gates running statically and simultaneously during the entire read access time. The dynamic operation of both decoders during each read access time would result in better performance, but the restrictions associated with the dynamic operation of diode logic would hinder this mode of operation.
Dynamic Row Address Decoder
With continued reference to
With reference to
Returning to the embodiment under discussion, when the P+ end of the memory diode is connected to a row line, reading the memory requires the selected row to be HIGH and the selected column to be LOW as discussed above.
In this embodiment, one way to enable dynamic row decoding is to bring the row and column conductors to logic HIGH (Step 700), for example, by bringing the row pullup element to logic HIGH, and bringing the column pulldown element to either logic HIGH or a high impedance (i.e., Hi Z) state. While the row and column conductors are charged, all of the row address inputs and the column address inputs are driven to logic HIGH. Next, the row pullup element is driven to logic LOW or a high impedance state (Step 704). The address of the selected row is subsequently applied to the row address bits of the row decoder input (Step 708), enabling the row address. Since the row pullup element is in a high-impedance state, enabling the row address bits does not create a static current flow. Only the selected row stays at logic HIGH, while the other rows are driven to logic LOW by the address bit diodes. Next, the address of the selected column is applied to the row address bits (Step 712). At this time the column pulldown element is in a high impedance state, so enabling the column address bits does not enable a static current flow. Finally, the column pulldown element is driven to logic LOW (Step 716). Only the selected column is pulled to logic LOW by the pulldown element, as the other columns remain in logic HIGH by the pullup connection of the column address bit diodes.
After this final step, the selected memory bit diode is now forward-biased, assuming that it is present and has closed contacts. The selected row discharges through the selected memory bit diode, bringing the selected row to logic LOW if the bit diode is present or leaving it in logic HIGH if the bit diode is either not present or has an open contact. It is these two states that are detected outside the memory array by the output-state detection circuitry (Step 720).
As discussed above, in the embodiment under discussion the selected column should be logic LOW to forward bias the selected memory bit diode. Since AND gates are possible with diode logic, the selected column determined by the inputs to the AND gate should be logic HIGH (or logic LOW for a negative logic implementation). If the gate is precharged, or operated dynamically, by definition the precharge state should be the same as the decoded state. As noted above, this presents a problem because the column decoder operates properly when precharged to the state opposite that of the decoded state. In contrast, the row decoder can be operated with the same state since it is the first block to be operated in the sequence above.
Consequentially, the column-address decoder should be operated in static mode for at least some fraction of the read access cycle. Accordingly, the column decoder gates, which should operate in static mode for some period, are either associated with all of the unselected columns or all of the unselected columns but one. For large nonsegmented arrays the number of unselected columns will be large. As an example, for a 1 Gb array, there are potentially 32,768 rows and 32,768 columns. So, in this example, 32,767 column-address decoders would operate with static power consumption during some part of the read access cycle.
Dynamic Column Address Decoder
The sequence for dynamic column address decoding is similar to the sequence for dynamic row address decoding with the row and column functionality exchanged. This similarity is one example of the symmetric nature of this circuit.
First, all of the row and column conductors are brought to logic LOW by bringing the row pullup element and the column pulldown element to logic LOW (Step 750). While the row and column conductors are charged, all of the row address inputs and column address inputs are driven to logic LOW. Next, the column pullup element is set to logic HIGH or a high impedance state (Step 754). The address of the selected column is applied to the column address bits of the column decoder input, enabling the column address (Step 758). Since the column pullup element is in an high-impedance state, enabling the column address bits does not create a static current flow. Only the selected column stays at logic LOW, while the other columns are driven to logic HIGH by the address bit diodes. Next, the address of the selected row is enabled (Step 762). At this time, the row pullup element is in a high impedance state, so enabling the row address bits does not enable a static current flow. Finally, the row pullup element is driven to logic HIGH (Step 766). Only the selected row is pulled to logic HIGH by the pullup element, as the other rows remain logic LOW by the pulldown connection of the row address bit diodes. At this point, the state of the memory diode is read from an output terminal (Step 770).
Output Column
A useful memory device should provide an output that represents the state of an addressed memory array bit. Typically this is a single output node for any addressed bit. As illustrated in
With reference to
Once again this output column may be operated statically or dynamically. If the OR matrix is operated statically then the row and column address decoders should also be operated statically, resulting in significant power consumption. Operated statically, the node out will be either logic HIGH or logic LOW depending on the state of the addressed bit location.
It should be noted that, as depicted in
If instead the output column is operated dynamically, then the common N+ end 800 of the diodes D6 at the end of each row should be driven to logic HIGH to put all of them in an OFF or a reverse bias state. This may be achieved by setting the node “oprch” 812 at the P+ end of the diode D7 to logic HIGH.
One advantage to dynamic operation is that when the diodes D6 are reverse-biased or OFF, any external load on the pin out cannot affect the internal rows or columns of the memory array (i.e., at the P+ end of the diodes D6). This differs from the static method of operating the output column OR gate, when setting any row to logic HIGH will also charge any external loading on the pin out through the forward-biased D6 diode.
In a further embodiment, D8 and the associated pin may optionally be removed (not shown).
Dummy Row Circuit
The diode memory array described above is basically an analog circuit. All of the components in the array are either diodes or nonlinear resistors. There is no gain or 3-terminal device such as a MOSFET or bipolar transistor.
It is known that most circuits operate better when measuring a differential voltage, as opposed to measuring a single-ended voltage such as the voltage at the output of this memory array, i.e., the absolute voltage at the node “out” 804. One approach to generating a differential voltage to sense a bit state in the diode memory array is to introduce a “dummy row” circuit, a “dummy column” circuit, or a combination of a dummy row circuit and a dummy column circuit together.
A dummy row circuit represents a row with a bit diode preset, such that the row voltage always discharges. In this case the differential operation would involve measuring the difference between the addressed row voltage (either charged and therefore logic HIGH, or discharged and therefore logic LOW) and the voltage of the dummy row, which is always discharged and therefore logic LOW.
The approach presented in
Depending on the particular application, there may be advantages to having a dummy row architecture in lieu of a dummy column architecture, vice versa, or an architecture with both a dummy row and a dummy column structure.
Dummy Column Architecture
The embodiment of
Accordingly,
The bias voltage 954 (“vbiasrow”) is approximately OV in simulation. In a full memory array this voltage should be determined by logic LOW voltage at the output of the selected column decoder and should be approximately one diode voltage drop. In certain applications, where the bias voltage 954 should be a diode voltage drop instead of a constant DC voltage, an on-chip diode may be introduced into the path between the bias voltage 1054 and the memory bit diodes 950 (not shown).
Yet another dummy column structure would omit the memory bit diodes 950 in their entirety and connect the P+ nodes of the output diodes 958 together (not shown). This structure assumes that for a dummy output column no charge will be transferred from the P+ side of the row output diodes 954 as the internal charge on a row is sampled. The voltage on the P+ side of those diodes 954 would therefore be expected to have little effect on the dummy output voltage.
Output Detection
One issue to be addressed in the use of passive diode arrays is reading the bit array from outside the package in a way that does not slow the part down. Conceptually, any wholly passive circuit will be sensitive to external loading, either capacitive or resistive. In a wholly passive circuit, there is no gain available to electrically isolate one part, e.g., the internal circuitry of the array, from another part, e.g., an external load from printed circuit board capacitance or the device pins of other integrated circuits. In contrast, conventional active integrated circuits utilize gain to electrically isolate one component, such as a digital output driver, from another.
In a passive memory device, this gain does not exist. Therefore, another approach must be used to isolate memory array timing from external loading. Various embodiments of the present invention approach this problem by operating the output column dynamically, thereby isolating the external loads from the internal memory array as described above.
One approach used to generate an external signal, which can be used to determine if the state of a selected internal memory array bit is a “1” or a “0,” utilizes a switched capacitor circuit.
The circuit in
With further reference to
If the voltage across capacitor C2, V2, is initially zero, then Vf reduces to
and the final voltage depends on the capacitance ratio between the capacitors. Accordingly, to maximize the signal to noise ratio, i.e., the change in V2, the output signal from the memory array, C2 should be made as small as possible.
Applying this concept to the diode memory array context requires the introduction of the equivalent of the switch SW1 to isolate the capacitance of the external load, C2, from the capacitance of the memory array, C1. One implementation of this approach is shown in
In
V3 in
The rows in the array, such as rowx, can now be discharged by a selected memory bit if there is a contact to the diode top, or remains undischarged if there is no contact and C1 is therefore not detectable (since D2 is OFF, i.e., reverse-biased). Setting
With
In this sequence of events, the voltage difference between the equal final voltages Vf on C1 and C2 when V3 is less than or greater than Vf is the output signal from the array. This output signal is now off-chip and potentially inside another device where SW1 and C2 are located.
One benefit of this approach is that the final voltage on C2 is not dependent on a closed-loop gain block such as an op amp. In fact, the charge transfer from node rowx will likely only be limited by the series resistance of diode D2. This RC-limited charge transfer can be very fast. For example, a 1 kΩ resistor and a 1 pF capacitor have an associated RC time constant of one nanosecond; these are reasonable device sizes for the memory arrays being considered. The RC time constants are also compatible with typical memory access rates of approximately less than 10 MHz.
It will therefore be seen that the foregoing represents a highly advantageous approach to the construction of diode memory arrays. The terms and expressions employed herein are used as terms of description and not of limitation and there is no intention, in the use of such terms and expressions, of excluding any equivalents of the features shown and described or portions thereof, but it is recognized that various modifications are possible within the scope of the invention claimed. For example, although the aforementioned embodiments depict diodes in a particular orientation, further embodiments of the present invention may utilize diodes in a different orientation and nothing in this discussion is intended to limit the scope of the present invention to embodiments illustrated in the figures. For example, one embodiment of the present invention utilizes semiconductor memory fabricated in three dimensions, such as the memory described in U.S. Pat. No. 6,956,757.
Therefore, it must be expressly understood that the illustrated embodiments have been shown only for the purposes of example and should not be taken as limiting the invention, which is defined by the following claims. The following claims are thus to be read as not only literally including what is set forth by the claims but also to include all equivalents that are insubstantially different, even though not identical in other respects to what is shown and described in the above illustrations.
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